Softening of an AA3103 Alloy Analysed Using Gallium Enhanced Microscopy

Hans Erik Ekström; O.V. Mishin; Lars Östensson; Joacim Hagström

doi:10.4028/www.scientific.net/MSF.519-521.1591

Paper Titles

Modelling of Microstructure and Texture and the Resulting Properties during the Thermo-Mechanical Processing of Aluminium Sheets
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Recrystallization of AA1050 Studied by 3DXRD
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In Situ SEM-EBSP Observations of Recrystallization Texture Formation in Al-3mass%Mg Alloy
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Effect of Thermomechanical Processing on Texture and Mechanical Properties of Al-Cu-Li Alloy Plate
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Softening of an AA3103 Alloy Analysed Using Gallium Enhanced Microscopy
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Boundary Mobilities in Binary Al-Mn Alloys
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Influence of Concurrent Precipitation on the Nucleation Kinetics during Recrystallisation in AA3003
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Deformation and Recrystallization Behaviour of a Homogenised and a Heterogenised Al-Mg-Si Alloy
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Changes in Grain Size Distribution of a Submicron Grained Al-Sc Alloy during High Temperature Annealing
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HomeMaterials Science ForumMaterials Science Forum Vols. 519-521Softening of an AA3103 Alloy Analysed Using...

Softening of an AA3103 Alloy Analysed Using Gallium Enhanced Microscopy

Abstract:

The softening behaviour during annealing was investigated in cold and hot rolled AA3103 alloys after different heat treatments. It was found that the evolution of boundary spacing determined using gallium enhanced microscopy gives a very good representation of the softening behaviour. The results show that cold rolled Al-Mn alloys soften by continuous growth of the subgrain structure, “continuous recrystallisation”, provided the pre-treatment of the ingots has been made to avoid too high a density of dispersoids and the cold rolling reduction has been very large. The very high strain creates a microstructure with a large fraction of high angle boundaries that are mostly parallel to the sheet surface. A recently developed subgrain growth model which takes the effect of solute drag into account, gives a good description of the softening kinetics. The solute drag is controlled by bulk diffusion of Mn. The simultaneous precipitation of Mn from the solid solution takes place by grain boundary diffusion of the Mn atoms mainly to pre-existing particles. The solute concentration decreases as the inverse of the boundary spacing, which is due to the grain growth mainly in the thickness (normal) direction.